Comprehensive Review of Synthesis, Optical Properties and Applications of Heteroarylphosphonates and Their Derivatives

This review focuses on optical properties of compounds in which at least one phosphonate group is directly attached to a heteroaromatic ring. Additionally, the synthesis and other applications of these compounds are addressed in this work. The influence of the phosphonate substituent on the properties of the described compounds is discussed and compared with other non-phosphorus substituents, with particular attention given to photophysical properties, such as UV-Vis absorption and emission, fluorescence quantum yield and fluorescence lifetime. Considering the presence of heteroatom, the collected material was divided into two parts, and a review of the literature of the last thirty years on heteroaryl phosphonates containing sulfur and nitrogen atoms in the aromatic ring was conducted.


Introduction
Heteroaryl-and arylphosphonates are useful compounds with a wide range of applications in various fields of chemistry and materials science, especially due to their valuable optical properties, so a look at them from this angle is the subject of this review [1,2].These compounds are particularly notable for their use as photosensitizers in water oxidation processes, specifically as ligands in ruthenium(II) polypyridyl complexes [3].The properties of these complexes can be finely tuned by substituting bipyridine ligands, resulting in enhanced performance and functionality.In the field of semiconductor technology, heteroarylphosphonates are used to produce nanocrystalline semiconductors.Moreover, ruthenium complexes incorporating heteroarylphosphonates serve as reliable sources of photoexcited electrons in molecular devices, finding applications in organic solar cells, fluorescent cation sensors, and other energy-transfer systems.The phosphonium groups also function as anchoring groups in nanocrystalline semiconductors without adversely affecting the optical properties of the light-emitting dyes.In analytical biochemistry, lanthanide complexes featuring 2-pyridylphosphonic acid as ligands are gaining importance, particularly in nuclear magnetic resonance imaging (MRI) [4].The formation of polynuclear species in solution can be exploited to create complex heteropolynuclear structures, enhancing the utility of these ligands.Heteroarylphosphonates also shine in the development of lanthanide-containing luminescent probes for analytical sensors, medical analyses and living cell or tissue imaging [5,6].Their solubility in water, high quantum yield and suitability for multiphoton excitation make them particularly attractive.Additionally, the strong co-ordination ability of phosphonic acids enhances the thermodynamic stability of these complexes.In the field of optoelectronics, heteroarylphosphonates serve as deepblue, fluorescent emitters for efficient single-layer organic light-emitting diodes (OLEDs), polymer light-emitting diodes (PLEDs) and perovskite quantum dot light-emitting diodes (QD-LEDs) [7,8].They also exhibit notable properties in proton-coupled electron transfer (PCET), which is a useful mechanism for reducing the redox potentials of high-valent transition metal complexes.The diverse substituents on heteroarylphosphonates make them valuable electrochemical and photochemical modifiers, enhancing the performance of photosensitized solar cells where Ru-bipyridine dyes are anchored to TiO 2 surfaces via carboxylic and phosphonic acid groups [9].Additionally, these compounds show promise as luminescent materials for sensing metal ions [10].This broad spectrum of applications underscores the significance of heteroarylphosphonates in advancing both fundamental research and technological innovation, and motivates the discovery of new synthetic methods for these compounds.Therefore, this was the reason for the interest in this group of compounds.However, there are no reports in the literature on this topic before 1994, hence this comprehensive review covers the period of 1994-2024.

Optical Properties, Synthesis and Applications of Heteroarylphosphonates and Their Derivatives 2.1. Heteroarylphosphonates with Heteroaryl Sulfur Atom
Oligothiophenes are a promising class of fluorescent molecules that have potential applications in photovoltaics and fluorescence sensing [11,12].They are employed as conducting molecules because of their favorable optical and electronic properties, as well as their stability.Electronic properties of oligothiophenes are tuneable based on the number of conjugated subunits and types of substituents on the subunits.
Thiophene-thiophene cross-coupling reactions have been used by Bair et al. for the synthesis of unsymmetrical bithiophenes and tetrathiophenes 1-4 containing bipyridine and phosphonic group (Scheme 1) [13].The ligands themselves revealed absorbance at 240 nm from thiophene, 275-290 nm from bipyridine and 350-430 nm assigned to a π→π* transition due to the entire thienylbipyridine unit.However, when attached to ruthenium, both their fluorescence and that of ruthenium were quenched.An additional effect of the co-ordination of ruthenium to compounds 1-4 via nitrogen atoms was the appearance of a new absorption band at 470 nm (Figure 1).
Molecules 2024, 29, x FOR PEER REVIEW 2 o organic light-emitting diodes (OLEDs), polymer light-emitting diodes (PLEDs) and p ovskite quantum dot light-emitting diodes (QD-LEDs) [7,8].They also exhibit nota properties in proton-coupled electron transfer (PCET), which is a useful mechanism reducing the redox potentials of high-valent transition metal complexes.The diverse s stituents on heteroarylphosphonates make them valuable electrochemical and pho chemical modifiers, enhancing the performance of photosensitized solar cells where bipyridine dyes are anchored to TiO2 surfaces via carboxylic and phosphonic acid gro [9].Additionally, these compounds show promise as luminescent materials for sens metal ions [10].This broad spectrum of applications underscores the significance of h eroarylphosphonates in advancing both fundamental research and technological inno tion, and motivates the discovery of new synthetic methods for these compounds.The fore, this was the reason for the interest in this group of compounds.However, there no reports in the literature on this topic before 1994, hence this comprehensive rev covers the period of 1994-2024.

Heteroarylphosphonates with Heteroaryl Sulfur Atom
Oligothiophenes are a promising class of fluorescent molecules that have poten applications in photovoltaics and fluorescence sensing [11,12].They are employed as c ducting molecules because of their favorable optical and electronic properties, as wel their stability.Electronic properties of oligothiophenes are tuneable based on the num of conjugated subunits and types of substituents on the subunits.
Thiophene-thiophene cross-coupling reactions have been used by Bair et al. for synthesis of unsymmetrical bithiophenes and tetrathiophenes 1-4 containing bipyrid and phosphonic group (Scheme 1) [13].The ligands themselves revealed absorbanc 240 nm from thiophene, 275-290 nm from bipyridine and 350-430 nm assigned to a π→ transition due to the entire thienylbipyridine unit.However, when attached to rutheniu both their fluorescence and that of ruthenium were quenched.An additional effect of co-ordination of ruthenium to compounds 1-4 via nitrogen atoms was the appearanc a new absorption band at 470 nm (Figure 1).The P(III) and P(IV)(O, S, Se)-substituted bithiophenes 5-8 were synthesized in low-togood yields (28-92%) (Scheme 2).The compared fluorescence quantum yields formed a series: 7 (27%, X = S) > 10 (21%, X = S) > 9, 10 (15-17%, X = O) [14], and they were significantly improved compared to 2,2 ′ -bithiophene.Each compound showed a broad absorption band ranging from 300 to 400 nm and a less intense band at higher energy (250-270 nm), assigned to the π→π* transition of the bithiophene ring system.The difference in the energy of the linear absorption band upon changing the phosphorus substituents was less than or equal to 9 nm, implying that there was little phosphorus resonance contribution to aromatic systems.There are no simple rules relating the emission properties to the chemical structures for this class of molecules.This is in contrast to the structure-property relationships for the absorption spectra, which showed distinct additive trends with structure changes.The compounds showed optical transparencies above 420 nm for 5, 6 or 430 nm for 7, 8, making them suitable candidates for optical power limiting (OPL) measurements at wavelengths across the violet-blue spectral region [15].The P(III) and P(IV)(O, S, Se)-substituted bithiophenes 5-8 were synthesized in lo to-good yields (28-92%) (Scheme 2).The compared fluorescence quantum yields form a series: 7 (27%, X = S) > 10 (21%, X = S) > 9, 10 (15-17%, X = O) [14], and they were sig icantly improved compared to 2,2′-bithiophene.Each compound showed a broad abso tion band ranging from 300 to 400 nm and a less intense band at higher energy (250nm), assigned to the π→π* transition of the bithiophene ring system.The difference in energy of the linear absorption band upon changing the phosphorus substituents was than or equal to 9 nm, implying that there was little phosphorus resonance contribut to aromatic systems.There are no simple rules relating the emission properties to chemical structures for this class of molecules.This is in contrast to the structure-prope relationships for the absorption spectra, which showed distinct additive trends with str ture changes.The compounds showed optical transparencies above 420 nm for 5, 6 or nm for 7, 8, making them suitable candidates for optical power limiting (OPL) measu ments at wavelengths across the violet-blue spectral region [15].The P(III) and P(IV)(O, S, Se)-substituted bithiophenes 5-8 were synthesized in lowto-good yields (28-92%) (Scheme 2).The compared fluorescence quantum yields formed a series: 7 (27%, X = S) > 10 (21%, X = S) > 9, 10 (15-17%, X = O) [14], and they were significantly improved compared to 2,2′-bithiophene.Each compound showed a broad absorption band ranging from 300 to 400 nm and a less intense band at higher energy (250-270 nm), assigned to the π→π* transition of the bithiophene ring system.The difference in the energy of the linear absorption band upon changing the phosphorus substituents was less than or equal to 9 nm, implying that there was little phosphorus resonance contribution to aromatic systems.There are no simple rules relating the emission properties to the chemical structures for this class of molecules.This is in contrast to the structure-property relationships for the absorption spectra, which showed distinct additive trends with structure changes.The compounds showed optical transparencies above 420 nm for 5, 6 or 430 nm for 7, 8, making them suitable candidates for optical power limiting (OPL) measurements at wavelengths across the violet-blue spectral region [15].Both phosphonic acids 11 and 12 were selected for studies on the dynamic response in layered assemblies because the emission band of 11 (350-550 nm) coincided with the absorption band of 12 (300-450 nm) (Scheme 2).Such overlapping spectra of two chromophores and the possibility of photoisomerization through ring rotation are useful in excitation transport studies [16,17].
Chan, Luh and co-workers have described the construction of the first organicinorganic hybrid materials (OIHM) from phosphonic acids and aluminum lactate [18].It is expected that these materials should act similarly to silicon-based materials and could be used in photovoltaic applications.The authors synthesized a series of phosphonic acids by coupling triethylphosphite with corresponding aryl bromides to obtain phosphonates.The phosphonates were then hydrolyzed with trimethylsilyl bromide, yielding phosphonic acids 13-17 (Scheme 3).
The absorption and emission peaks were measured for the compounds 14-16, and their wavelengths increased in the series 14, 16  in layered assemblies because the emission band of 11 (350-550 nm) coincided with the absorption band of 12 (300-450 nm) (Scheme 2).Such overlapping spectra of two chromophores and the possibility of photoisomerization through ring rotation are useful in excitation transport studies [16,17].
Chan, Luh and co-workers have described the construction of the first organic-inorganic hybrid materials (OIHM) from phosphonic acids and aluminum lactate [18].It is expected that these materials should act similarly to silicon-based materials and could be used in photovoltaic applications.The authors synthesized a series of phosphonic acids by coupling triethylphosphite with corresponding aryl bromides to obtain phosphonates.The phosphonates were then hydrolyzed with trimethylsilyl bromide, yielding phosphonic acids 13-17 (Scheme 3).Scheme 3. Synthesis of bis(aryl-and heteroaryl)phosphonic acids 13-17.
The absorption and emission peaks were measured for the compounds 14-16, and their wavelengths increased in the series 14, 16 2) [20].The goal of the study was to deepen the understanding of the photophysical properties of chalcogenorhodamine dyes.The procedure is illustrated by the synthesis of compound 18 (Scheme 4).Compounds 19-20 exhibited red-shift when compared to the unsubstituted compounds.All the compounds were relatively stable, with moderate lifetimes.The authors rationalized their photochemical findings by assigning them to an excited state with charge separation.

Heteroarylphosphonates with Heteroaryl Nitrogen
Photophysical properties and diverse applications (optoelectronics, metal ion detection, imaging tools, fluorescence probes, photosensitisers, catalysis, etc.) of compounds with heteroaryl nitrogen are widely described in the literature [21][22][23][24][25][26].The presence of Compounds 19-20 exhibited red-shift when compared to the unsubstituted compounds.All the compounds were relatively stable, with moderate lifetimes.The authors rationalized their photochemical findings by assigning them to an excited state with charge separation.Compounds 19-20 exhibited red-shift when compared to the unsubstituted compounds.All the compounds were relatively stable, with moderate lifetimes.The authors rationalized their photochemical findings by assigning them to an excited state with charge separation.

Heteroarylphosphonates with Heteroaryl Nitrogen
Photophysical properties and diverse applications (optoelectronics, metal ion detection, imaging tools, fluorescence probes, photosensitisers, catalysis, etc.) of compounds with heteroaryl nitrogen are widely described in the literature [21][22][23][24][25][26].The presence of donor atoms in the molecule, such as nitrogen in the heteroaromatic system and oxygen atoms in the phosphonate group, enables the formation of co-ordination complexes, therefore, the vast majority of compounds presented in this part are ligands and their complexes, particularly with d 10 metal ions, which generated significant interest due to their photoluminescent properties.Presented ligands are also highly effective at chelating lanthanide cations due to their strong electrostatic interactions and near-neutral second pKa values.Compared to carboxylates, phosphonates are bulkier and provide greater steric hindrance, which is beneficial for shielding luminescent Ln cations from water molecules that cause luminescence loss through nonradiative quenching.Heteroarylphosphonates were also used as electron injectors in PLED devices or chromophore sensitizers.
Charbonnière and co-workers have presented complexes with ligands based on azacrown ethers functionalized with phosphonate groups [29].They were interested in obtaining a system in which photonic up-conversion, i.e., conversion of low-energy photons to visible ones, could take place.The synthesis of ligand 30 involved a single decarboxylation and P-functionalization step.It was achieved by the oxidation of the pyridine derivative to pyridine N-oxide and subsequent treatment with ethyl chloroformate and triethyl phosphite.Then, chloride moieties were substituted with nitrogen atoms from 1,4,7-triazacyclononane followed by hydrolysis of all phosphonate ester groups to form 30 (Scheme 5).It has been shown that ligand 30 formed stable LnL complexes with Ln = La, Lu, Eu, Tb and Yb.Ligand 30 exhibited an absorption peak at 267 nm (in 0.01 M Tris-HCl), which could be attributed to  →  * transitions of the pyridine phosphonate group.It has also been proven that Yb, Tb and Eu complexes showed emission peaks at approximately 1000, 550 and 620 nm, respectively rendering them highly luminescent.The formation of polynuclear complexes [(LnL)2Lnx] for x = 1, 2, 3 was driven by the strong polarization of the ligand due to the electron-rich phosphonated pendant arms.For example, the deuterated analogue YbL2D used in the formation of [(YbL2D)2Tbx] complexes (x = 1-3) afforded characteristic visible UC emission of Tb upon NIR excitation of the Yb at 980 nm.
Synthetic methodologies have been developed for the preparation of ligands 31 and 32, which were chelators based on 1,4,7-triazacyclonane and pyclene (Scheme 6) [30].Both ligands were obtained in high yields and utilized in a comprehensive photophysical study involving complexation with Eu 3+ , Tb 3+ and Yb 3+ .The addition of the solution of the Yb 3+ salt resulted in a bathochromic shift of the maximum from 268 to 271 nm, together with the appearance of a shoulder at ca. 275 nm, characteristic of complexation of the pyridyl phosphonate moieties.Similar results were observed in the case of Eu 3+ and Tb 3+ .Spectroscopic characterization of the Ln 3+ complexes of 31 and 32 was done in water and D2O, and showed the effective sensitization of the lanthanide metal-centered emission spectra, each exhibiting typical lanthanide emission bands.It has been shown that ligand 30 formed stable LnL complexes with Ln = La, Lu, Eu, Tb and Yb.Ligand 30 exhibited an absorption peak at 267 nm (in 0.01 M Tris-HCl), which could be attributed to π → π * transitions of the pyridine phosphonate group.It has also been proven that Yb, Tb and Eu complexes showed emission peaks at approximately 1000, 550 and 620 nm, respectively rendering them highly luminescent.The formation of polynuclear complexes [(LnL) 2 Ln x ] for x = 1, 2, 3 was driven by the strong polarization of the ligand due to the electron-rich phosphonated pendant arms.For example, the deuterated analogue YbL 2 D used in the formation of [(YbL 2 D) 2 Tb x ] complexes (x = 1-3) afforded characteristic visible UC emission of Tb upon NIR excitation of the Yb at 980 nm.
Synthetic methodologies have been developed for the preparation of ligands 31 and 32, which were chelators based on 1,4,7-triazacyclonane and pyclene (Scheme 6) [30].Both ligands were obtained in high yields and utilized in a comprehensive photophysical study involving complexation with Eu 3+ , Tb 3+ and Yb 3+ .The addition of the solution of the Yb 3+ salt resulted in a bathochromic shift of the maximum from 268 to 271 nm, together with the appearance of a shoulder at ca. 275 nm, characteristic of complexation of the pyridyl phosphonate moieties.Similar results were observed in the case of Eu 3+ and Tb 3+ .Spectroscopic characterization of the Ln 3+ complexes of 31 and 32 was done in water and D 2 O, and showed the effective sensitization of the lanthanide metal-centered emission spectra, each exhibiting typical lanthanide emission bands.
The synthesis of the two ligands 35 and 36 from amines 33 and 34, and then the formation of heteropolymetallic complex Lu-35, were presented by Charbonnière et al. (Scheme 7) [31].This spectroscopically silent lutetium analogue was used to determine the emissive properties of the ligand 35.From the phosphorescent emission measured at 77 K, the energy level of the triplet state was determined to be 27,930 cm −1 , and the corresponding lifetime was found to be 462 ± 2 ms.A series of lanthanide complexes was prepared with 35, and the solution, structural, potentiometric and photophysical properties of these complexes were investigated.The synthesis of the two ligands 35 and 36 from amines 33 and 34, and then the formation of heteropolymetallic complex Lu-35, were presented by Charbonnière et al. (Scheme 7) [31].This spectroscopically silent lutetium analogue was used to determine the emissive properties of the ligand 35.From the phosphorescent emission measured at 77 K, the energy level of the triplet state was determined to be 27930 cm -1 , and the corresponding lifetime was found to be 462 ± 2 ms.A series of lanthanide complexes was prepared with 35, and the solution, structural, potentiometric and photophysical properties of these complexes were investigated.Zheng et al. published the first example of iridium/dysprosium phosphonate for single-molecule magnets (SMMs) and photoelectronics [32].Complex 38 showed both fieldinduced slow magnetization relaxation and photoluminescence, so it could be successfully used in SMMs and photoelectronics (Scheme 8).The synthesis was straightforward and could be accomplished by the treatment of an iridium-phosphonic acid complex with dysprosium(III) trifluoromethanesulfonate, which yielded compound 38.The synthesis of the two ligands 35 and 36 from amines 33 and 34, and then the formation of heteropolymetallic complex Lu-35, were presented by Charbonnière et al. (Scheme 7) [31].This spectroscopically silent lutetium analogue was used to determine the emissive properties of the ligand 35.From the phosphorescent emission measured at 77 K, the energy level of the triplet state was determined to be 27930 cm -1 , and the corresponding lifetime was found to be 462 ± 2 ms.A series of lanthanide complexes was prepared with 35, and the solution, structural, potentiometric and photophysical properties of these complexes were investigated.Zheng et al. published the first example of iridium/dysprosium phosphonate for single-molecule magnets (SMMs) and photoelectronics [32].Complex 38 showed both fieldinduced slow magnetization relaxation and photoluminescence, so it could be successfully used in SMMs and photoelectronics (Scheme 8).The synthesis was straightforward and could be accomplished by the treatment of an iridium-phosphonic acid complex with dysprosium(III) trifluoromethanesulfonate, which yielded compound 38.Zheng et al. published the first example of iridium/dysprosium phosphonate for single-molecule magnets (SMMs) and photoelectronics [32].Complex 38 showed both fieldinduced slow magnetization relaxation and photoluminescence, so it could be successfully used in SMMs and photoelectronics (Scheme 8).The synthesis was straightforward and could be accomplished by the treatment of an iridium-phosphonic acid complex with dysprosium(III) trifluoromethanesulfonate, which yielded compound 38.
The absorption spectra showed that 38 exhibited six times more intensive absorption than 37. Furthermore, emission spectra suggested that 38 was slightly more blue-shifted than 37.
Zheng, Ma and co-workers synthesized the series of iridium complexes 39-42 containing the phosphonic acid moiety for usage in photoelectronics [33].Moreover, complexes 41 and 42 contained a fluorine atom as well (Figure 4).
The synthesis involved simple complexation of Ir(2-(2-pyridinyl)phenyl)Cl 2 with a corresponding pyridine derivative, prepared according to the procedure in the literature.In emission spectra studies, complex 39 showed a yellow emission peak at 506 nm, while compound 40 was significantly red-shifted and its peak intensity was about 10 times lower than that of 39.Similarly for 41 and 42, the emission peaks were at 476 nm and 568 nm, respectively.Scheme 8. Synthesis of iridium complex 38 from complex 37.
The absorption spectra showed that 38 exhibited six times more intensive absorption than 37. Furthermore, emission spectra suggested that 38 was slightly more blue-shifted than 37.
Zheng, Ma and co-workers synthesized the series of iridium complexes 39-42 containing the phosphonic acid moiety for usage in photoelectronics [33].Moreover, complexes 41 and 42 contained a fluorine atom as well (Figure 4).The synthesis involved simple complexation of Ir(2-(2-pyridinyl)phenyl)Cl2 with a corresponding pyridine derivative, prepared according to the procedure in the literature.In emission spectra studies, complex 39 showed a yellow emission peak at 506 nm, while compound 40 was significantly red-shifted and its peak intensity was about 10 times lower than that of 39.Similarly for 41 and 42, the emission peaks were at 476 nm and 568 nm, respectively.
Hollow-core photonic crystal fibers (HC-PCFs) provide a novel approach for in situ UV-Vis spectroscopy with enhanced detection sensitivity.Euser et al. demonstrated that longer optical path lengths than those afforded by conventional cuvette-based UV-Vis spectroscopy can be used to detect and identify the Co(I) and Co(II) states in hydrogenevolving cobaloxime catalysts with a Ru(II)-based photosensitizer.Cobalt complexes with various groups in the axial position, such as the chloride group [CoCl2(dmgH)(dmgH2)] Scheme 8. Synthesis of iridium complex 38 from complex 37. Scheme 8. Synthesis of iridium complex 38 from complex 37.
The absorption spectra showed that 38 exhibited six times more intensive absorption than 37. Furthermore, emission spectra suggested that 38 was slightly more blue-shifted than 37.
Zheng, Ma and co-workers synthesized the series of iridium complexes 39-42 containing the phosphonic acid moiety for usage in photoelectronics [33].Moreover, complexes 41 and 42 contained a fluorine atom as well (Figure 4).The synthesis involved simple complexation of Ir(2-(2-pyridinyl)phenyl)Cl2 with a corresponding pyridine derivative, prepared according to the procedure in the literature.In emission spectra studies, complex 39 showed a yellow emission peak at 506 nm, while compound 40 was significantly red-shifted and its peak intensity was about 10 times lower than that of 39.Similarly for 41 and 42, the emission peaks were at 476 nm and 568 nm, respectively.
Hollow-core photonic crystal fibers (HC-PCFs) provide a novel approach for in situ UV-Vis spectroscopy with enhanced detection sensitivity.Euser et al. demonstrated that longer optical path lengths than those afforded by conventional cuvette-based UV-Vis spectroscopy can be used to detect and identify the Co(I) and Co(II) states in hydrogenevolving cobaloxime catalysts with a Ru(II)-based photosensitizer.Cobalt complexes with various groups in the axial position, such as the chloride group [CoCl2(dmgH)(dmgH2)] Hollow-core photonic crystal fibers (HC-PCFs) provide a novel approach for in situ UV-Vis spectroscopy with enhanced detection sensitivity.Euser et al. demonstrated that longer optical path lengths than those afforded by conventional cuvette-based UV-Vis spectroscopy can be used to detect and identify the Co(I) and Co(II) states in hydrogenevolving cobaloxime catalysts with a Ru(II)-based photosensitizer.Cobalt complexes with various groups in the axial position, such as the chloride group [CoCl 2 (dmgH)(dmgH 2 )] (dmg: dimethylglyoxime) 43, the pyridyl group [CoCl(dmgH) 2 py] 44 and the pyridyl group with phosphonate substituent 45, were selected as model compounds for these studies (Figure 5) [34,35].
Luminescent lanthanide helicates, self-assembled from ditopic ligands 46-49 bearing phosphonic acid or phosphoester units, were studied by Bünzli et al. (Figure 6) [36].Photophysical measurements revealed sensitization of the metal-centered luminescence in the europium and terbium complexes, which was modulated by the nature of the ligand.The absorption spectra of the deprotonated ligands 46-52 feature two main bands located around 310 nm (32,260 cm −1 ), 217 nm (46,080 cm −1 ) and a shoulder at 240 nm (41,670 cm −1 ), mainly involving orbitals located on the aromatic rings and phosphoryl groups.At 295 K, UV excitation in the π → π* absorption bands results in a broad emission band with a maximum between 25,500 and 29,500 cm −1 for the ligands, and between 24,250-28,500 cm −1 for the complexes with Lu and Gd.Luminescent lanthanide helicates, self-assembled from ditopic ligands 46-49 bearing phosphonic acid or phosphoester units, were studied by Bünzli et al. (Figure 6) [36].Photophysical measurements revealed sensitization of the metal-centered luminescence in the europium and terbium complexes, which was modulated by the nature of the ligand.The absorption spectra of the deprotonated ligands 46-52 feature two main bands located around 310 nm (32260 cm −1 ), 217 nm (46080 cm −1 ) and a shoulder at 240 nm (41670 cm −1 ), mainly involving orbitals located on the aromatic rings and phosphoryl groups.At 295 K, UV excitation in the π→π* absorption bands results in a broad emission band with a maximum between 25500 and 29500 cm −1 for the ligands, and between 24250-28500 cm −1 for the complexes with Lu and Gd.The 46-49 series of ligands acted similarly to the 50-52 ligands with regard to the coordination of the lanthanide ion (Ln = Eu, Gd, Tb), and the replacement of the carboxylates by a phosphoester substituent on the pyridine ring was a valuable alternative to the grafting of a poly(oxyethylene) arm with respect to solubility.Preliminary results indicated that [Eu2(47)3] did indeed penetrate into live HeLa cells and were potential candidates for lanthanide luminescent probes.
Pyridine diphosphonate ligand 53 was used for the stabilization of tetravalent uranium and neptunium in an aqueous medium under aerobic conditions (Figure 7).Raman, UV-Vis, fluorescence and cyclic voltametric studies, along with density functional theory (DFT) calculations, were conducted to obtain structural insights into these complexes in different oxidation states [37].Luminescent lanthanide helicates, self-assembled from ditopic ligands 46-49 bearing phosphonic acid or phosphoester units, were studied by Bünzli et al. (Figure 6) [36].Photophysical measurements revealed sensitization of the metal-centered luminescence in the europium and terbium complexes, which was modulated by the nature of the ligand.The absorption spectra of the deprotonated ligands 46-52 feature two main bands located around 310 nm (32260 cm −1 ), 217 nm (46080 cm −1 ) and a shoulder at 240 nm (41670 cm −1 ), mainly involving orbitals located on the aromatic rings and phosphoryl groups.At 295 K, UV excitation in the π→π* absorption bands results in a broad emission band with a maximum between 25500 and 29500 cm −1 for the ligands, and between 24250-28500 cm −1 for the complexes with Lu and Gd.The 46-49 series of ligands acted similarly to the 50-52 ligands with regard to the coordination of the lanthanide ion (Ln = Eu, Gd, Tb), and the replacement of the carboxylates by a phosphoester substituent on the pyridine ring was a valuable alternative to the grafting of a poly(oxyethylene) arm with respect to solubility.Preliminary results indicated that [Eu2(47)3] did indeed penetrate into live HeLa cells and were potential candidates for lanthanide luminescent probes.
Pyridine diphosphonate ligand 53 was used for the stabilization of tetravalent uranium and neptunium in an aqueous medium under aerobic conditions (Figure 7).Raman, UV-Vis, fluorescence and cyclic voltametric studies, along with density functional theory (DFT) calculations, were conducted to obtain structural insights into these complexes in different oxidation states [37].The 46-49 series of ligands acted similarly to the 50-52 ligands with regard to the coordination of the lanthanide ion (Ln = Eu, Gd, Tb), and the replacement of the carboxylates by a phosphoester substituent on the pyridine ring was a valuable alternative to the grafting of a poly(oxyethylene) arm with respect to solubility.Preliminary results indicated that [Eu 2 (47) 3 ] did indeed penetrate into live HeLa cells and were potential candidates for lanthanide luminescent probes.
Pyridine diphosphonate ligand 53 was used for the stabilization of tetravalent uranium and neptunium in an aqueous medium under aerobic conditions (Figure 7).Raman, UV-Vis, fluorescence and cyclic voltametric studies, along with density functional theory (DFT) calculations, were conducted to obtain structural insights into these complexes in different oxidation states [37].

Bipyridinephosphonic Acids and Derivatives
Phosphonate ligands are widely used for extracting 'f' block elements.Three N,Odonor N-heterocyclic aromatic diphosphonate ligands 53-55 were tested for Am 3+ and Eu 3+ extraction/separation (Figure 7) [38].Luminescence titration in an aqueous medium showed formation of the anionic complex with Eu 3+ .Liquid-liquid extraction with Aliquat-336 revealed the 1:3 metal-ligand stoichiometry for the acid 53, the 1:2 metal-ligand stoichiometry for acid 54, and both 1:2 and 1:3 stoichiometry for the acid 55.DFT calculations predicted their structures, and electrospray ionization mass spectrometry confirmed the calculations.Non-selectivity towards Am 3+ and Eu 3+ was due to unfavorable covalent interactions in the metal-ligand bonds.

Bipyridinephosphonic Acids and Derivatives
Phosphonate ligands are widely used for extracting 'f' block elements.Three N,Odonor N-heterocyclic aromatic diphosphonate ligands 53-55 were tested for Am 3+ and Eu 3+ extraction/separation (Figure 7) [38].Luminescence titration in an aqueous medium showed formation of the anionic complex with Eu 3+ .Liquid-liquid extraction with Aliquat-336 revealed the 1:3 metal-ligand stoichiometry for the acid 53, the 1:2 metal-ligand stoichiometry for acid 54, and both 1:2 and 1:3 stoichiometry for the acid 55.DFT calculations predicted their structures, and electrospray ionization mass spectrometry confirmed the calculations.Non-selectivity towards Am 3+ and Eu 3+ was due to unfavorable covalent interactions in the metal-ligand bonds.
The synthesis and characterization of three ligands 156, 57 and 58 with phosphonic groups were described by Charbonnière et al. (Figure 8).As has been shown, in contrast to acid 57, which acted as a heptadentate ligand, ligand 56 did not form stable complexes with lanthanide cations in aqueous solutions (0.01 M Tris/HCl, pH 7.0).Probably, the negative charge brought by the phosphonate functions largely counterbalanced the positive charge of the lanthanide cations.The UV-visible absorption spectrum of ligand 57 in water showed distinct transitions at 237 and 289 nm, accompanied by a shoulder at 315 nm.Excitation at 320 nm resulted in emission at 407 nm, attributed to 1 π→π* transitions.Upon complexation with lanthanides, absorption bands shifted, suggesting ligand-to-metal sensitization.However, the resulting metal-centered luminescence displayed low quantum yields compared to reference complexes [39].Phosphonic acid 58 can form stable complexes with lanthanide cations, which form polynuclear species in the presence of an excess of lanthanides.The UV-Vis absorption spectrum of the free ligand was dominated by the intense π→π* transitions of pyridine units at 267 nm (ε = 14,700 M −1 cm −1 ) [4,40].

Bipyridinephosphonic Acids and Derivatives
Phosphonate ligands are widely used for extracting 'f' block elements.Three N,Odonor N-heterocyclic aromatic diphosphonate ligands 53-55 were tested for Am 3+ and Eu 3+ extraction/separation (Figure 7) [38].Luminescence titration in an aqueous medium showed formation of the anionic complex with Eu 3+ .Liquid-liquid extraction with Aliquat-336 revealed the 1:3 metal-ligand stoichiometry for the acid 53, the 1:2 metal-ligand stoichiometry for acid 54, and both 1:2 and 1:3 stoichiometry for the acid 55.DFT calculations predicted their structures, and electrospray ionization mass spectrometry confirmed the calculations.Non-selectivity towards Am 3+ and Eu 3+ was due to unfavorable covalent interactions in the metal-ligand bonds.
The synthesis and characterization of three ligands 156, 57 and 58 with phosphonic groups were described by Charbonnière et al. (Figure 8).As has been shown, in contrast to acid 57, which acted as a heptadentate ligand, ligand 56 did not form stable complexes with lanthanide cations in aqueous solutions (0.01 M Tris/HCl, pH 7.0).Probably, the negative charge brought by the phosphonate functions largely counterbalanced the positive charge of the lanthanide cations.The UV-visible absorption spectrum of ligand 57 in water showed distinct transitions at 237 and 289 nm, accompanied by a shoulder at 315 nm.Excitation at 320 nm resulted in emission at 407 nm, attributed to 1 π→π* transitions.Upon complexation with lanthanides, absorption bands shifted, suggesting ligand-to-metal sensitization.However, the resulting metal-centered luminescence displayed low quantum yields compared to reference complexes [39].Phosphonic acid 58 can form stable complexes with lanthanide cations, which form polynuclear species in the presence of an excess of lanthanides.The UV-Vis absorption spectrum of the free ligand was dominated by the intense π→π* transitions of pyridine units at 267 nm (ε = 14 700 M -1 cm -1 ) [4,40].Polypyridyl complexes, whose properties can be easily tuned by substituting bipyridine ligands with phosphonate groups, are used as photosensitizers.Such compounds can play a distinctive role in catalysis and significantly affect the efficiency of water oxidation to produce hydrogen using sunlight.They should provide visible light absorption, a long-lived excited state to improve electron transfer to the catalyst or the sacrificial agent, Polypyridyl complexes, whose properties can be easily tuned by substituting bipyridine ligands with phosphonate groups, are used as photosensitizers.Such compounds can play a distinctive role in catalysis and significantly affect the efficiency of water oxidation to produce hydrogen using sunlight.They should provide visible light absorption, a long-lived excited state to improve electron transfer to the catalyst or the sacrificial agent, high stability under catalytic conditions, and are particularly suitable redox potentials for catalyst oxidation at all necessary oxidation stages.
Mulyana et al. investigated four phosphorus-based ruthenium complexes, 59-61 and 63, as photocatalysts for water decomposition (Figure 9, Scheme 4) [41].The idea was to create a system in which Ru 2+ cations are oxidized to Ru 3+ , while hydrogen ions are reduced to elemental hydrogen.Ru 2+ cations can then be regenerated by the treatment with EDTA.
catalyst oxidation at all necessary oxidation stages.
Mulyana et al. investigated four phosphorus-based ruthenium complexes, 59-61 and 63, as photocatalysts for water decomposition (Figure 9, Scheme 4) [41].The idea was to create a system in which Ru 2+ cations are oxidized to Ru 3+ , while hydrogen ions are reduced to elemental hydrogen.Ru 2+ cations can then be regenerated by the treatment with EDTA.The authors prepared complexes 59-61 according to the previous reports.Complex 63 was synthesized by the addition of ruthenium(III) chloride to 4,4′-di-t-butyl-2,2′-bipyridine, followed by a reaction of complex 62 with a 4,4′-diethoxyphosphoryl-2,2′-bipyridine phosphonate ligand.Finally, phosphonate diesters were converted to the corresponding phosphonic acids 63 with TMS-Br (Scheme 9).The studies showed that 61 possessed the highest photocurrent and the highest excited state lifetime.Scheme 9. Synthesis of the complex 63.
Ruile and co-workers designed a set of Ru(II) complexes for photoelectrical devices based on TiO2.The authors synthesized the phosphonate ligand by coupling 4-bromo-2,2′bipyridine with diethylphosphite, followed by hydrolysis with aqueous hydrochloric acid and an addition of potassium thiocyanate (Scheme 10) [42].The authors prepared complexes 59-61 according to the previous reports.Complex 63 was synthesized by the addition of ruthenium(III) chloride to 4,4′-di-t-butyl-2,2′-bipyridine, followed by a reaction of complex 62 with a 4,4′-diethoxyphosphoryl-2,2′-bipyridine phosphonate ligand.Finally, phosphonate diesters were converted to the corresponding phosphonic acids 63 with TMS-Br (Scheme 9).The studies showed that 61 possessed the highest photocurrent and the highest excited state lifetime.Scheme 9. Synthesis of the complex 63.
Ruile and co-workers designed a set of Ru(II) complexes for photoelectrical devices based on TiO2.The authors synthesized the phosphonate ligand by coupling 4-bromo-2,2′bipyridine with diethylphosphite, followed by hydrolysis with aqueous hydrochloric acid and an addition of potassium thiocyanate (Scheme 10) [42].
Scheme 9. Synthesis of the complex 63.
Ruile and co-workers designed a set of Ru(II) complexes for photoelectrical devices based on TiO 2 .The authors synthesized the phosphonate ligand by coupling 4-bromo-2,2 ′bipyridine with diethylphosphite, followed by hydrolysis with aqueous hydrochloric acid and an addition of potassium thiocyanate (Scheme 10) [42].As it turned out, compound 64 existed in two isomeric forms, in which the phosphonic acid group was placed cis or trans with respect to the thiocyanate.It was proven that the isomer ratio was 1:6 (cis to trans).What is more, the authors showed that 64 sensitized TiO2 efficiently, but with lower incident monochromatic photon-electron conversion energy (IPCE).The phosphonic acid group made the complex less easily desorbed upon exposure to water, making it a perfect anchoring group.
Concepcion et al. synthesized a series of Ru(II) complexes, 65-68, for application in artificial photosynthesis as oxidation catalysts (Figure 10) [43].As it turned out, compound 64 existed in two isomeric forms, in which the phosphonic acid group was placed cis or trans with respect to the thiocyanate.It was proven that the isomer ratio was 1:6 (cis to trans).What is more, the authors showed that 64 sensitized TiO 2 efficiently, but with lower incident monochromatic photon-electron conversion energy (IPCE).The phosphonic acid group made the complex less easily desorbed upon exposure to water, making it a perfect anchoring group.
As it turned out, compound 64 existed in two isomeric forms, in which the phosphonic acid group was placed cis or trans with respect to the thiocyanate.It was proven that the isomer ratio was 1:6 (cis to trans).What is more, the authors showed that 64 sensitized TiO2 efficiently, but with lower incident monochromatic photon-electron conversion energy (IPCE).The phosphonic acid group made the complex less easily desorbed upon exposure to water, making it a perfect anchoring group.
Concepcion et al. synthesized a series of Ru(II) complexes, 65-68, for application in artificial photosynthesis as oxidation catalysts (Figure 10) [43].The synthesis of ligands 72 for 65-66 complexes had not been reported previously and it involved the Stille coupling of 2-bromo-pyridine 70 with the stannane 69, followed by another coupling of the resulting product 71 with diethylphosphite (Scheme 11).All of the complexes exhibited absorption peaks at approximately 650 nm and 460 nm, and emission peaks near 630 nm.The former could be attributed to metal-ligand charge transfer.It was also found that the complexes were rather non-fluorescent, as their quantum yields varied from 0.0128 (for 68) to 0.0379 (for 65).The synthesis of ligands 72 for 65-66 complexes had not been reported previously and it involved the Stille coupling of 2-bromo-pyridine 70 with the stannane 69, followed by another coupling of the resulting product 71 with diethylphosphite (Scheme 11).All of the complexes exhibited absorption peaks at approximately 650 nm and 460 nm, and emission peaks near 630 nm.The former could be attributed to metal-ligand charge transfer.It was also found that the complexes were rather non-fluorescent, as their quantum yields varied from 0.0128 (for 68) to 0.0379 (for 65).Bignozzi, Cano-Boquera et al. designed a strategy for the preparation of cis ruthenium complexes, which contained phosphonate moieties [44].The authors hoped the complexes would be used in optoelectronics as photosensitizers.The synthesis involved the complexation of ruthenium(II) salt with bipyridine, yielding compounds 73 and 74 (Scheme 12).Bignozzi, Cano-Boquera et al. designed a strategy for the preparation of cis ruthenium complexes, which contained phosphonate moieties [44].The authors hoped the complexes would be used in optoelectronics as photosensitizers.The synthesis involved the complexation of ruthenium(II) salt with bipyridine, yielding compounds 73 and 74 (Scheme 12).
The phosphonate complexes 73 and 74 were hydrolyzed to phosphonic acids 75 and 76, and then chlorine atoms were replaced with cyanide or thiocyanide, giving compounds 77-80.The NMR spectra showed that some protons of the bipyridine unit could be shifted as far as 10.1 ppm, due to the formation of the ring current circulation on pyridine.The spectroscopic measurements showed that complexes 73-80 exhibited blue-shift in the absorption spectrum, compared to analogous carbonyl compounds.Moreover, the authors studied these complexes as photosensitizers in solar cells, but compounds 73-80 showed less efficiency compared to carbonyl analogs.However, 4,4 ′ -substituted bipyridyl complexes 73 and 77 revealed higher photoconversion efficiencies than 5,5 ′ -substituted ones.Bignozzi, Cano-Boquera et al. designed a strategy for the preparation of cis ruthenium complexes, which contained phosphonate moieties [44].The authors hoped the complexes would be used in optoelectronics as photosensitizers.The synthesis involved the complexation of ruthenium(II) salt with bipyridine, yielding compounds 73 and 74 (Scheme 12).Scheme 12. Synthesis and spectroscopic data of complexes 73-80 (absorption maximum measured in 0.1 N sulfuric acid; emission maximum measured for the anionic forms of the complexes at room temperature in deaerated methanol; emission lifetimes for the anionic forms of the complexes).
The phosphonate complexes 73 and 74 were hydrolyzed to phosphonic acids 75 and 76, and then chlorine atoms were replaced with cyanide or thiocyanide, giving compounds 77-80.The NMR spectra showed that some protons of the bipyridine unit could be shifted as far as 10.1 ppm, due to the formation of the ring current circulation on pyridine.The spectroscopic measurements showed that complexes 73-80 exhibited blue-shift in the absorption spectrum, compared to analogous carbonyl compounds.Moreover, the authors studied these complexes as photosensitizers in solar cells, but compounds 73-80 showed less efficiency compared to carbonyl analogs.However, 4,4′-substituted bipyridyl  Scheme 12. Synthesis and spectroscopic data of complexes 73-80 (absorption maximum measured in 0.1 N sulfuric acid; emission maximum measured for the anionic forms of the complexes at room temperature in deaerated methanol; emission lifetimes for the anionic forms of the complexes).
Rosser, Windle and Reisner described the synthesis and spectral studies of Mn(II) complex 82 containing a phosphonic acid moiety (Scheme 13) [46].Compound 82 contained only earth-abundant elements and could be used as a catalyst for the CO 2 reduction to CO.The synthesis of 82 was accomplished by the complexation of pentacarbonyl manganese(I) bromide with 4,4 ′ -bis(phosphonic acid)-2,2 ′ -bipyridine 81.
Rosser, Windle and Reisner described the synthesis and spectral studies of Mn(II) complex 82 containing a phosphonic acid moiety (Scheme 13) [46].Compound 82 contained only earth-abundant elements and could be used as a catalyst for the CO2 reduction to CO.The synthesis of 82 was accomplished by the complexation of pentacarbonyl manganese(I) bromide with 4,4′-bis(phosphonic acid)-2,2′-bipyridine 81.Scheme 13.Synthesis of complex 82.
The authors showed that the reduction of CO2 proceeded by the reduction of Mn(I) to the dimeric Mn(0) species 83, which then reduced carbon dioxide with regeneration of 82 (Scheme 14).Scheme 13.Synthesis of complex 82.
The authors showed that the reduction of CO 2 proceeded by the reduction of Mn(I) to the dimeric Mn(0) species 83, which then reduced carbon dioxide with regeneration of 82 (Scheme 14).Scheme 13.Synthesis of complex 82.
The authors showed that the reduction of CO2 proceeded by the reduction of Mn(I) to the dimeric Mn(0) species 83, which then reduced carbon dioxide with regeneration of 82 (Scheme 14).Scheme 14. Synthesis of the dimer 83 and the regeneration of complex 82.
FT-IR spectra have shown an increase in the intensity of absorption and the broadening of bands near 1950-2100 cm −1 upon the deposition of 82 on the TiO2 electrode.UV-Vis spectra have displayed bands near 400-500, 640 and 820 nm, which could be attributed to the formation of the Mn(0)-Mn(0) bond, which was not present before or after the reduction of CO2, thus confirming the proposed mechanism.
Ho, Hannongbua and co-workers have investigated iridium(III) complexes 84 and 63 containing phosphonate moieties for optoelectronics (Figure 11) [47].The authors tested various anchoring groups and concluded that phosphonate derivatives outperformed Scheme 14. Synthesis of the dimer 83 and the regeneration of complex 82.
FT-IR spectra have shown an increase in the intensity of absorption and the broadening of bands near 1950-2100 cm −1 upon the deposition of 82 on the TiO 2 electrode.UV-Vis spectra have displayed bands near 400-500, 640 and 820 nm, which could be attributed to the formation of the Mn(0)-Mn(0) bond, which was not present before or after the reduction of CO 2 , thus confirming the proposed mechanism.
Ho, Hannongbua and co-workers have investigated iridium(III) complexes 84 and 63 containing phosphonate moieties for optoelectronics (Figure 11) [47].The authors tested various anchoring groups and concluded that phosphonate derivatives outperformed classical carbonyl anchors.The synthesis consisted of the substitution of IrCl 3 with different ligands, which were prepared according to the literature procedures or bought from commercial sources.The authors found that Ir-complex 85 exhibited more intensive and red-shifted light absorption than 84, due to its extended conjugation.Furthermore, the authors tested 84 and 85 as photosensitizers in the light-driven hydrogen generation studies on Pt-TiO2 surfaces.It was shown that both compounds outclassed their carbonyl-containing counterparts, which could be attributed to better anchoring.Compound 85 gave the highest turnover value for this process.
A luminescent Pt(II) complex, 86, was successfully synthesized and its two-way vapochromic behavior was investigated (Figure 12) [48].Emission spectroscopy revealed that the 86•5H2O complex exhibited an orange emission at 585 nm that shifted in two directions, to a blue-green emission at 469 nm by drying at 100 °C, or to a red emission at 701 nm by drying under vacuum at room temperature.The comparable distances around the Pt(II) ions observed in 86 and 87 suggested that substitution of the carboxylic acid groups at the 4,4′-positions of the bpy ligand for phosphonic acid groups hardly affected the electronic state of the Pt(II) ion.The authors found that Ir-complex 85 exhibited more intensive and red-shifted light absorption than 84, due to its extended conjugation.Furthermore, the authors tested 84 and 85 as photosensitizers in the light-driven hydrogen generation studies on Pt-TiO 2 surfaces.It was shown that both compounds outclassed their carbonyl-containing counterparts, which could be attributed to better anchoring.Compound 85 gave the highest turnover value for this process.
A luminescent Pt(II) complex, 86, was successfully synthesized and its two-way vapochromic behavior was investigated (Figure 12) [48].Emission spectroscopy revealed that the 86•5H 2 O complex exhibited an orange emission at 585 nm that shifted in two directions, to a blue-green emission at 469 nm by drying at 100 • C, or to a red emission at 701 nm by drying under vacuum at room temperature.The comparable distances around the Pt(II) ions observed in 86 and 87 suggested that substitution of the carboxylic acid groups at the 4,4 ′ -positions of the bpy ligand for phosphonic acid groups hardly affected the electronic state of the Pt(II) ion.
the 86•5H2O complex exhibited an orange emission at 585 nm that shifted in two directions, to a blue-green emission at 469 nm by drying at 100 °C, or to a red emission at 701 nm by drying under vacuum at room temperature.The comparable distances around the Pt(II) ions observed in 86 and 87 suggested that substitution of the carboxylic acid groups at the 4,4′-positions of the bpy ligand for phosphonic acid groups hardly affected the electronic state of the Pt(II) ion.Schmehl and co-workers described the synthesis of bipyridyl complexes of Ru(II) for light-harvesting and -sensitization [49].For this application, they synthesized six ligands: three phosphonates 88-90 and three corresponding phosphonic acids (Scheme 15).The synthesis of 88 involved the coupling of aryl bromide with diethylphosphite, while phosphonate 89 was obtained by the Arbuzov reaction.Schmehl and co-workers described the synthesis of bipyridyl complexes of Ru(II) for light-harvesting and -sensitization [49].For this application, they synthesized six ligands: three phosphonates 88-90 and three corresponding phosphonic acids (Scheme 15).The synthesis of 88 involved the coupling of aryl bromide with diethylphosphite, while phosphonate 89 was obtained by the Arbuzov reaction.Ru(II) complexes of ligands 88-90 showed luminescence at room and low temperatures, with moderate lifetimes.The authors showed that [(bpy)2Ru(90)] 2+ exhibited a significant blue-shift in the emission spectrum upon hydrolysis to the corresponding acid.The effect was attributed to the large difference in the electron-accepting ability between 90 and its corresponding acid.It was also shown that the luminescence of phosphonic acid complexes could be quenched by the addition of Cu(II) or Fe(III) ions in non-aqueous solvents.
A series of four ligands, based on a 5′-methyl-2,2′-bipyridyl framework substituted in the 6 positions of 91, 92, 93 and 94, were described by Ziessel et al. (Figure 13) [50].As was shown, the lanthanide complexes of the phosphonic acid derivatives were up to two orders of magnitude more stable than those of the carboxylic acid ligand.The absorption spectra of the ligands featured two main bands (with additional shoulders) located around 250 nm and 305 nm, and assigned to π→π* transitions, mainly located on the pyridine units for the latter, while the former contained substantial contributions from the carboxylic (91) or phosphoryl groups (92-94).The ligand-centered luminescence of the studied complexes displayed essentially the same features as the free ligand luminescence.Ru(II) complexes of ligands 88-90 showed luminescence at room and low temperatures, with moderate lifetimes.The authors showed that [(bpy) 2 Ru(90)] 2+ exhibited a significant blue-shift in the emission spectrum upon hydrolysis to the corresponding acid.The effect was attributed to the large difference in the electron-accepting ability between 90 and its corresponding acid.It was also shown that the luminescence of phosphonic acid complexes could be quenched by the addition of Cu(II) or Fe(III) ions in non-aqueous solvents.
A series of four ligands, based on a 5 ′ -methyl-2,2 ′ -bipyridyl framework substituted in the 6 positions of 91, 92, 93 and 94, were described by Ziessel et al. (Figure 13) [50].As was shown, the lanthanide complexes of the phosphonic acid derivatives were up to two orders of magnitude more stable than those of the carboxylic acid ligand.The absorption spectra of the ligands featured two main bands (with additional shoulders) located around 250 nm and 305 nm, and assigned to π→π* transitions, mainly located on the pyridine units for the latter, while the former contained substantial contributions from the carboxylic (91) or phosphoryl groups (92-94).The ligand-centered luminescence of the studied complexes displayed essentially the same features as the free ligand luminescence.The deprotonation of the bipy core of 92 at the pH range of 1.21-8.03was not accompanied by the classical hypsochromic shift in the UV-Vis absorption spectra from 308 nm to 290 nm, which was usually associated with the cis−trans isomerization.The authors explained the unusual behavior by the presence of the phosphonate group, which kept stabilizing the cis form D by intramolecular hydrogen bonding, thereby maintaining the corresponding π→π* transitions at low energies.Only when the last proton was removed at higher pH values (E) did the nitrogen lone pair repulsion become large enough to induce the hypsochromic shift.Similar behavior was not observed for the other ligands as no Hbonding interaction could stabilize the non-protonated bipy subunit.

Terpyridinephosphonic Acids and Derivatives
UV-visible spectra were obtained for 95-97 as a function of pH, and these data suggested that the observed pKas corresponded to deprotonation of a bound water molecule, for example [Ru(bpyPO3)(bpy)(OH2)]→[Ru(bpyPO3)(bpy)(OH)] − , indicating that the bound chloride ions in 95, 96 and 97 were displaced by aqua ligands upon dissolution (Figure 14) [51].Each compound was found to exhibit proton-coupled electron transfer (PCET), and under aqueous conditions 97 oxidized secondary C−H bonds using sodium periodate (NaIO4) as the primary oxidant.Zenkina et al. synthesized a terpyridyl ester, 98, and acid 99 which was used as a ligand in Fe 2+ , Fe 3+ , Ru 3+ and Zn 2+ complexes (Scheme 16) [10].They aimed to obtain a The deprotonation of the bipy core of 92 at the pH range of 1.21-8.03was not accompanied by the classical hypsochromic shift in the UV-Vis absorption spectra from 308 nm to 290 nm, which was usually associated with the cis−trans isomerization.The authors explained the unusual behavior by the presence of the phosphonate group, which kept stabilizing the cis form D by intramolecular hydrogen bonding, thereby maintaining the corresponding π→π* transitions at low energies.Only when the last proton was removed at higher pH values (E) did the nitrogen lone pair repulsion become large enough to induce the hypsochromic shift.Similar behavior was not observed for the other ligands as no H-bonding interaction could stabilize the non-protonated bipy subunit.

Terpyridinephosphonic Acids and Derivatives
UV-visible spectra were obtained for 95-97 as a function of pH, and these data suggested that the observed pK a s corresponded to deprotonation of a bound water molecule, for example [Ru(bpyPO 3 )(bpy)(OH 2 )]→[Ru(bpyPO 3 )(bpy)(OH)] − , indicating that the bound chloride ions in 95, 96 and 97 were displaced by aqua ligands upon dissolution (Figure 14) [51].Each compound was found to exhibit proton-coupled electron transfer (PCET), and under aqueous conditions 97 oxidized secondary C−H bonds using sodium periodate (NaIO 4 ) as the primary oxidant.The deprotonation of the bipy core of 92 at the pH range of 1.21-8.03was not accompanied by the classical hypsochromic shift in the UV-Vis absorption spectra from 308 nm to 290 nm, which was usually associated with the cis−trans isomerization.The authors explained the unusual behavior by the presence of the phosphonate group, which kept stabilizing the cis form D by intramolecular hydrogen bonding, thereby maintaining the corresponding π→π* transitions at low energies.Only when the last proton was removed at higher pH values (E) did the nitrogen lone pair repulsion become large enough to induce the hypsochromic shift.Similar behavior was not observed for the other ligands as no Hbonding interaction could stabilize the non-protonated bipy subunit.

Terpyridinephosphonic Acids and Derivatives
UV-visible spectra were obtained for 95-97 as a function of pH, and these data suggested that the observed pKas corresponded to deprotonation of a bound water molecule, for example [Ru(bpyPO3)(bpy)(OH2)]→[Ru(bpyPO3)(bpy)(OH)] − , indicating that the bound chloride ions in 95, 96 and 97 were displaced by aqua ligands upon dissolution (Figure 14) [51].Each compound was found to exhibit proton-coupled electron transfer (PCET), and under aqueous conditions 97 oxidized secondary C−H bonds using sodium periodate (NaIO4) as the primary oxidant.Zenkina et al. synthesized a terpyridyl ester, 98, and acid 99 which was used as a ligand in Fe 2+ , Fe 3+ , Ru 3+ and Zn 2+ complexes (Scheme 16) [10].They aimed to obtain a Zenkina et al. synthesized a terpyridyl ester, 98, and acid 99 which was used as a ligand in Fe 2+ , Fe 3+ , Ru 3+ and Zn 2+ complexes (Scheme 16) [10].They aimed to obtain a sensor that could be used in logic gates to detect these ions in concentrations as low as parts per billion.As shown in Scheme 16, 4 ′ -{[(trifluoromethyl)sulfonyl]oxy}-2,2 ′ :6 ′ ,2 ′′ -terpyridine was coupled with diethylphosphite in the presence of tetrakis(triphenylphosphine)palladium(0), producing the phosphonate derivative 98.The phosphonic acid ligand 99 was obtained by treating the corresponding ester with a diluted aqueous solution of hydrochloric acid.The authors added the ligand to the solutions of corresponding metal cations, yielding complexes 100-103, however, only structure 100 has been crystallographically determined.
Molecules 2024, 29, x FOR PEER REVIEW 19 of 31 sensor that could be used in logic gates to detect these ions in concentrations as low as parts per billion.As shown in Scheme 16, 4′-{[(trifluoromethyl)sulfonyl]oxy}-2,2′:6′,2″-terpyridine was coupled with diethylphosphite in the presence of tetrakis(triphenylphosphine)palladium(0), producing the phosphonate derivative 98.The phosphonic acid ligand 99 was obtained by treating the corresponding ester with a diluted aqueous solution of hydrochloric acid.The authors added the ligand to the solutions of corresponding metal cations, yielding complexes 100-103, however, only structure 100 has been crystallographically determined.
Scheme 16.The synthesis of terpyridyl ligand 99 for the identification of ions Fe(II), Fe(III), Ru(III) and Zn(II) in dilute aqueous solutions.
As typical for such structures, the metal-ligand absorption bands were observed.At 290 nm, only complexes 102 and 103 showed absorption, while at 400 nm only complexes 100 and 102 absorbed light.At 560 nm, only 100 showed absorption.The detection of 102 was possible due to strong fluorescence at 360 nm upon excitation at 326 nm.Thus, it was possible to simultaneously differentiate and measure concentrations of Fe 2+ , Zn 2+ , Ru 3+ and Fe 3+ in the presence of ligand 99.
A molecular ruthenium aqua complex, 104, was synthesised from terpyridinephosphonic ester 98 or acid 99, and grafted by phosphonate group to mesoporous silica and silica-coated magnetic particles onto two independent paths A and B (Scheme 17) [52].The UV-Vis spectra of 98 exhibited ligand-based π→π* bands below 350 nm and relatively intense bands above 350 nm, mainly due to dπ(Ru)→π*(L) metal-to-ligand charge-transfer transitions, similar to those obtained for homogeneous complex, which indicated that electronic properties remained unchanged.The catalytic performance and the reutilization of these hybrid materials were explored in the epoxidation of alkenes with PhI(OAc)2.
Scheme 16.The synthesis of terpyridyl ligand 99 for the identification of ions Fe(II), Fe(III), Ru(III) and Zn(II) in dilute aqueous solutions.
As typical for such structures, the metal-ligand absorption bands were observed.At 290 nm, only complexes 102 and 103 showed absorption, while at 400 nm only complexes 100 and 102 absorbed light.At 560 nm, only 100 showed absorption.The detection of 102 was possible due to strong fluorescence at 360 nm upon excitation at 326 nm.Thus, it was possible to simultaneously differentiate and measure concentrations of Fe 2+ , Zn 2+ , Ru 3+ and Fe 3+ in the presence of ligand 99.
A molecular ruthenium aqua complex, 104, was synthesised from terpyridinephosphonic ester 98 or acid 99, and grafted by phosphonate group to mesoporous silica and silica-coated magnetic particles onto two independent paths A and B (Scheme 17) [52].The UV-Vis spectra of 98 exhibited ligand-based π→π* bands below 350 nm and relatively intense bands above 350 nm, mainly due to dπ(Ru)→π*(L) metal-to-ligand charge-transfer transitions, similar to those obtained for homogeneous complex, which indicated that electronic properties remained unchanged.The catalytic performance and the reutilization of these hybrid materials were explored in the epoxidation of alkenes with PhI(OAc) 2 .
The photoinduced charge separation in three different assemblies composed of an electron donor D and based on ligand 99 chromophore sensitizer S adsorbed on nanocrystalline TiO 2 films by a phosphonate group to efficiently convert light into electrical energy was investigated by Bonhôte et al. (Scheme 18, Figure 15) [53].In all of the systems, the sensitizer was a ruthenium(II) bis-terpyridine complex and the donor was a 4-(N,N-di-p-anisylamino) phenyl group linked to the 4 ′ position of the terpyridine, either directly (105) or via a benzyl ether interlocking group (106).In the third system, sensitizer 107 and donor 108 were co-adsorbed on the surface.Absorption spectra of heterotriads 105|TiO 2 , 106|TiO 2, and 107,108|TiO 2 under positive polarization (0.5 V), after 10 min.illumination, showed a new strong absorption band with a maximum in the range of 730-750 nm.Light-induced excitation of the sensitizer S was followed by electron injection (a, Figure 16) into the TiO 2 and oxidation (b) of the donor D. Lateral conduction (c) inside the monolayer allowed electrons to flow from the SnO 2 (d) to the oxidized donors.The photoinduced charge separation in three different assemblies composed of an electron donor D and based on ligand 99 chromophore sensitizer S adsorbed on nanocrystalline TiO2 films by a phosphonate group to efficiently convert light into electrical energy was investigated by Bonhôte et al. (Scheme 18, Figure 15) [53].In all of the systems, the sensitizer was a ruthenium(II) bis-terpyridine complex and the donor was a 4-(N,N-di-panisylamino) phenyl group linked to the 4′ position of the terpyridine, either directly (105) or via a benzyl ether interlocking group (106).In the third system, sensitizer 107 and donor 108 were co-adsorbed on the surface.Absorption spectra of heterotriads 105|TiO2, 106|TiO2, and 107,108|TiO2 under positive polarization (0.5 V), after 10 min.illumination, showed a new strong absorption band with a maximum in the range of 730-750 nm.Lightinduced excitation of the sensitizer S was followed by electron injection (a, Figure 16) into the TiO2 and oxidation (b) of the donor D. Lateral conduction (c) inside the monolayer allowed electrons to flow from the SnO2 (d) to the oxidized donors.The photoinduced charge separation in three different assemblies composed of an electron donor D and based on ligand 99 chromophore sensitizer S adsorbed on nanocrystalline TiO2 films by a phosphonate group to efficiently convert light into electrical energy was investigated by Bonhôte et al. (Scheme 18, Figure 15) [53].In all of the systems, the sensitizer was a ruthenium(II) bis-terpyridine complex and the donor was a 4-(N,N-di-panisylamino) phenyl group linked to the 4′ position of the terpyridine, either directly (105) or via a benzyl ether interlocking group (106).In the third system, sensitizer 107 and donor 108 were co-adsorbed on the surface.Absorption spectra of heterotriads 105|TiO2, 106|TiO2, and 107,108|TiO2 under positive polarization (0.5 V), after 10 min.illumination, showed a new strong absorption band with a maximum in the range of 730-750 nm.Lightinduced excitation of the sensitizer S was followed by electron injection (a, Figure 16) into the TiO2 and oxidation (b) of the donor D. Lateral conduction (c) inside the monolayer allowed electrons to flow from the SnO2 (d) to the oxidized donors.

Phenantrolinephosphonic Acids and Derivatives
Complexes with a phosphonate group in the five-position of the phenanthroline ligand have also been described by Rau et al. [54].As it turned out, the substitution pattern used only slightly changed photophysical properties of the compounds, compared to the reference molecule 109 in the aqueous medium (Scheme 19).However, conversion of diethyl phosphonate ester in 109 to the corresponding phosphonic acid 110 drastically reduced photostability in water.The water oxidation catalytic experiments of compound 110 showed the best performance.111 demonstrated very poor catalytic performance, although it had good stability and higher oxidation potential compared to 110.The cationic photosensitizers 109 and [Ru(bpy)3](PF6)2 were unable to provide any photocatalytic activity.

Phenantrolinephosphonic Acids and Derivatives
Complexes with a phosphonate group in the five-position of the phenanthroline ligand have also been described by Rau et al. [54].As it turned out, the substitution pattern used only slightly changed photophysical properties of the compounds, compared to the reference molecule 109 in the aqueous medium (Scheme 19).However, conversion of diethyl phosphonate ester in 109 to the corresponding phosphonic acid 110 drastically reduced photostability in water.The water oxidation catalytic experiments of compound 110 showed the best performance.111 demonstrated very poor catalytic performance, although it had good stability and higher oxidation potential compared to 110.The cationic photosensitizers 109 and [Ru(bpy) 3 ](PF 6 ) 2 were unable to provide any photocatalytic activity.Mulfort and co-workers designed a series of Cu(I) phenantroline complexes including hexafluorophosphate complex 112 (Figure 17) [55].The goal was to study the directionality of metal-ligand charge transfer in these complexes to further understand the localization of electronic excited states.The authors were able to show that 112 shifted the localization the most towards the phosphorus-containing ring.The ligands were synthesized according to previously reported procedures-the synthesis involved the coupling of 4,7-dibromo-1,10-phenanthroline with triethyl phosphite.Compound 112 contained the most electron-withdrawing group in the investigated complexes, which made the absorption peak the most red-shifted to approximately 500 nm.Mulfort and co-workers designed a series of Cu(I) phenantroline complexes including hexafluorophosphate complex 112 (Figure 17) [55].The goal was to study the directionality of metal-ligand charge transfer in these complexes to further understand the localization of electronic excited states.The authors were able to show that 112 shifted the localization the most towards the phosphorus-containing ring.Mulfort and co-workers designed a series of Cu(I) phenantroline complexes including hexafluorophosphate complex 112 (Figure 17) [55].The goal was to study the directionality of metal-ligand charge transfer in these complexes to further understand the localization of electronic excited states.The authors were able to show that 112 shifted the localization the most towards the phosphorus-containing ring.The ligands were synthesized according to previously reported procedures-the synthesis involved the coupling of 4,7-dibromo-1,10-phenanthroline with triethyl phosphite.Compound 112 contained the most electron-withdrawing group in the investigated complexes, which made the absorption peak the most red-shifted to approximately 500 nm.The ligands were synthesized according to previously reported procedures-the synthesis involved the coupling of 4,7-dibromo-1,10-phenanthroline with triethyl phosphite.Compound 112 contained the most electron-withdrawing group in the investigated complexes, which made the absorption peak the most red-shifted to approximately 500 nm.The ligands were synthesized according to previously reported procedures-the synthesis involved the coupling of 4,7-dibromo-1,10-phenanthroline with triethyl phosphite.Compound 112 contained the most electron-withdrawing group in the investigated complexes, which made the absorption peak the most red-shifted to approximately 500 nm.The fluorescence emission peaks for compounds 114-116 were approximately the same as for 2-pyrazinephosphonic acid, all observed near 470 nm.However, the authors The fluorescence emission peaks for compounds 114-116 were approximately the same as for 2-pyrazinephosphonic acid, all observed near 470 nm.However, the authors noticed that the emission intensity increased with increased rigidity of 2-pyrazinephosphonic acid in forming the co-ordination polymers.Thus, the fluorescence intensity increased in the series: 113 < 114 < 115 < 116.It was also shown that 116 had the highest quantum yield of 1.55%.
Heteroaromatic compounds with phosphoryl group, such as 117 and 118, or the amide group 119, when deposited on a stable and defined calixarene structure, acted as ligands complexing lanthanides and actinides (Figure 19) [57,58].The analysis using ligand solutions of different concentrations indicated that, for all three ligands, the absorption bands were in the wavelength region of 285 nm-400 nm, followed Beer's Law and were suitable for spectrophotometry (Figure 20).noticed that the emission intensity increased with increased rigidity of 2-pyrazinephosphonic acid in forming the co-ordination polymers.Thus, the fluorescence intensity increased in the series: 113 < 114 < 115 < 116.It was also shown that 116 had the highest quantum yield of 1.55%.Heteroaromatic compounds with phosphoryl group, such as 117 and 118, or the amide group 119, when deposited on a stable and defined calixarene structure, acted as ligands complexing lanthanides and actinides (Figure 19) [57,58].The analysis using ligand solutions of different concentrations indicated that, for all three ligands, the absorption bands were in the wavelength region of 285 nm-400 nm, followed Beer's Law and were suitable for spectrophotometry (Figure 20).All three ligands formed the 1:1 metal-ligand complex with Eu 3+ , and the stability constants followed the order: 119 < 117 < 118.This trend could be interpreted by the difference in the basicity of the functional groups and the steric effects of the ligands.Two pendant arms of the ligand co-ordinate to Eu 3+ in a tridentate mode, and the other two arms were either non-bonded or very weakly bonded with the metal ion (Figure 19).
Jackson, Muimo et al. designed and synthesized analogs of τand π-phosphohistidine (phosphopyrazole 120 and pyridyl amino amide 121), which were used to generate polyclonal antibodies (Scheme 20) [59].The compounds were subsequently tested in immunological studies concerning the selectivity of the antibodies produced by 120 and 121.The synthesis of both compounds involved the same key steps, namely the introduction of the diethoxyphosphoryl group by coupling (EtO) 2 P(O)H with the corresponding aryl bromide, followed by hydrolysis of the phosphonate ester with trimethylsilyl bromide to form phosphonic acids 120 and 121.Furthermore, immunofluorescence studies have shown that 120-121-induced antibodies were present throughout human bronchial epithelial cells, as well as in human neurons, with their higher concentration near the nucleus.
A report on a series of water-soluble aminophenoxazines that were evaluated for vital imaging in cell biology using an enzymatic synthetic strategy as an alternative to the nitrosative or chemical oxidative coupling of phenolic precursors was synthesized by Brynaert et al. [60].Thus, the 1,9-bis-phosphorylated aminophenoxazinone dye 122 was synthesized in 90% yield by taking advantage of laccase-enzyme-mediated oxidation in water (Scheme 21).The UV-Vis spectra of compound 122 showed absorption at 241 and 438 nm, with a high ε value of 8.8 × 10 3 M −1 cm −1 .However, the fluorescence quenching observed when 122 was mixed with Mg 2+ and/or Ca 2+ brought about a heavy handicap in the cell labeling application.On the other hand, this could lead to its development as a sensor for variations in divalent cation concentrations in the high range.
The synthesis of both compounds involved the same key steps, namely the introduction of the diethoxyphosphoryl group by coupling (EtO)2P(O)H with the corresponding aryl bromide, followed by hydrolysis of the phosphonate ester with trimethylsilyl bromide to form phosphonic acids 120 and 121.Furthermore, immunofluorescence studies have shown that 120-121-induced antibodies were present throughout human bronchial epithelial cells, as well as in human neurons, with their higher concentration near the nucleus.A report on a series of water-soluble aminophenoxazines that were evaluated for vital imaging in cell biology using an enzymatic synthetic strategy as an alternative to the nitrosative or chemical oxidative coupling of phenolic precursors was synthesized by Brynaert et al. [60].Thus, the 1,9-bis-phosphorylated aminophenoxazinone dye 122 was synthesized in 90% yield by taking advantage of laccase-enzyme-mediated oxidation in water (Scheme 21).The UV-Vis spectra of compound 122 showed absorption at 241 and 438 nm, with a high ε value of 8.8 × 10 3 M −1 cm −1 .However, the fluorescence quenching observed when 122 was mixed with Mg 2+ and/or Ca 2+ brought about a heavy handicap in the cell labeling application.On the other hand, this could lead to its development as a sensor for variations in divalent cation concentrations in the high range.

Carbazolephosphonic Acids and Derivatives
A solution-processable, deep-blue fluorescent emitter, 124 (TPCA), and its optical properties were compared with prototype 123 (TBCA) (Figure 21) [61].The identical optical band gap demonstrated that the electronic structure of the excited state was independent of the attached surface groups.In addition, TPCA in the film showed a red-shift of 8 nm compared to TBCA, due to a solvation effect.The corresponding non-doped, singlelayer SMOLED with TPCA showed a peak current efficiency about three orders of magnitude higher than that of the prototype with tert-butyl substituents.

Carbazolephosphonic Acids and Derivatives
A solution-processable, deep-blue fluorescent emitter, 124 (TPCA), and its optical properties were compared with prototype 123 (TBCA) (Figure 21) [61].The identical optical band gap demonstrated that the electronic structure of the excited state was independent of the attached surface groups.In addition, TPCA in the film showed a red-shift of 8 nm compared to TBCA, due to a solvation effect.The corresponding non-doped, single-layer SMOLED with TPCA showed a peak current efficiency about three orders of magnitude higher than that of the prototype with tert-butyl substituents.
properties were compared with prototype 123 (TBCA) (Figure 21) [61].The identical optical band gap demonstrated that the electronic structure of the excited state was independent of the attached surface groups.In addition, TPCA in the film showed a red-shift of 8 nm compared to TBCA, due to a solvation effect.The corresponding non-doped, singlelayer SMOLED with TPCA showed a peak current efficiency about three orders of magnitude higher than that of the prototype with tert-butyl substituents.Ding and co-workers reported the application of aryl phosphine oxide and phosphonate as an electron injection layer (EIL) used in polymer light-emitting diodes (PLEDs) [62].The aryl phosphine oxide displayed high conductivity, while the phosphonate 127 (TPPO) was a good electron injector.Thus, the EIL inherited both of these properties.The synthesis of phosphonate 127 is especially worth attention.It involved the Suzuki coupling between the pinacol boronic ester 125 and tri-(p-bromophenyl)phosphine oxide 126 in the presence of palladium(II) acetate and potassium carbonate in a mixture of ethylene glycol monomethyl (EGME) and water (Scheme 22) [63].As reported, the optical band gap for 127 was 3.49 eV.The absorption peak was observed at 250 nm, while the emission fell at 370 nm.The authors also recorded the phosphorescence spectrum at low temperatures Ding and co-workers reported the application of aryl phosphine oxide and phosphonate as an electron injection layer (EIL) used in polymer light-emitting diodes (PLEDs) [62].The aryl phosphine oxide displayed high conductivity, while the phosphonate 127 (TPPO) was a good electron injector.Thus, the EIL inherited both of these properties.The synthesis of phosphonate 127 is especially worth attention.It involved the Suzuki coupling between the pinacol boronic ester 125 and tri-(p-bromophenyl)phosphine oxide 126 in the presence of palladium(II) acetate and potassium carbonate in a mixture of ethylene glycol monomethyl (EGME) and water (Scheme 22) [63].As reported, the optical band gap for 127 was 3.49 eV.The absorption peak was observed at 250 nm, while the emission fell at 370 nm.The authors also recorded the phosphorescence spectrum at low temperatures with the maximum observed at approximately 520 nm.It was concluded that phosphonate 127 could be used as an electron injector in PLED devices.Moreover, such an application would be favorable if one desired to reduce the possibility of luminescence-quenching by energy transfer from an emitter to 127.
The same authors also used compounds 124 and 127 for the passivation of perovskite quantum dots in PeQLEDs, compensating for lead defects, common in such structures (Figure 22, Scheme 22) [64].The authors found that the P=O bond co-ordinated the exposed Pb atoms, significantly improving photoluminescence quantum yields.It was also proven that the usage of 124 in such systems was slightly advantageous to 127 since 124 could be dispersed more easily.Photoluminescence spectra of the perovskite quantum dots used, and those doped with 127 or 124, showed an emission peak at 518 nm, indicating that neither the amine nor the phosphine oxide changed the emission.Moreover, the lifetimes increased by 10 or 5 ns (124 and 127, respectively), indicating that the non-radiative exciton decay was suppressed.
Phosphonate-functionalized triaryl phosphine oxide 127 (TPPO) has been used for the successful fabrication of high-performance, solution-processed multilayer PLEDs (Figure 22) [63].According to the absorption onset of 127, the optical band gap was estimated to be 3.49 eV, and the corresponding emission fell into the ultraviolet region with a peak at 371 nm.The phosphorescent spectrum of 127 in toluene was recorded at 77 K and the calculated triplet energy level was about 2.65 eV, which was mainly determined by the biphenyl moiety.This suggested that 127 might also be suitable for green and red phosphorescent devices.
It was found that the inclusion of an additional TPPO layer resulted in an approximately 16-fold increase in the device performance compared to a control single-layer device without 127.
with the maximum observed at approximately 520 nm.It was concluded that phosphonate 127 could be used as an electron injector in PLED devices.Moreover, such an application would be favorable if one desired to reduce the possibility of luminescence-quenching by energy transfer from an emitter to 127.The same authors also used compounds 124 and 127 for the passivation of perovskite quantum dots in PeQLEDs, compensating for lead defects, common in such structures (Figure 22, Scheme 22) [64].The authors found that the P=O bond co-ordinated the exposed Pb atoms, significantly improving photoluminescence quantum yields.It was also proven that the usage of 124 in such systems was slightly advantageous to 127 since 124 could be dispersed more easily.Photoluminescence spectra of the perovskite quantum dots used, and those doped with 127 or 124, showed an emission peak at 518 nm, indicating that neither the amine nor the phosphine oxide changed the emission.Moreover, the lifetimes increased by 10 or 5 ns (124 and 127, respectively), indicating that the non-radiative exciton decay was suppressed.
Phosphonate-functionalized triaryl phosphine oxide 127 (TPPO) has been used for the successful fabrication of high-performance, solution-processed multilayer PLEDs (Figure 22) [63].According to the absorption onset of 127, the optical band gap was estimated to be 3.49 eV, and the corresponding emission fell into the ultraviolet region with a peak at 371 nm.The phosphorescent spectrum of 127 in toluene was recorded at 77 K and the calculated triplet energy level was about 2.65 eV, which was mainly determined by the biphenyl moiety.This suggested that 127 might also be suitable for green and red phosphorescent devices.
It was found that the inclusion of an additional TPPO layer resulted in an approximately 16-fold increase in the device performance compared to a control single-layer device without 127.

Conclusions
This review, covering the period of 1994-2024, discussed methods for the synthesis and applications of heteroarylphosphonates and their complexes with metals utilizing their optical properties.Heteroaryl moieties of the described compounds contain nitrogen and sulfur atoms in the ring, but the vast majority involve pyridine derivatives, and they are often associated with the easy availability of these derivatives and their good complexforming properties.The introduction of phosphonate groups makes it possible to manipulate the electronic and optical properties of the described compounds, but also to anchor them on metal oxide surfaces for device applications.In the construction of optoelectronic devices based on D-π-A structure, the presence of phosphonate groups ensures good solubility and the ability to produce good-quality, single layers in wet processes.This can improve the electron injection and transporting capability.The lack of a major influence on the emission wavelength and photoluminescence quantum yield of the molecule is also of great importance in this case.The heteroarylphosphonates are also widely used in coordination chemistry as ligands in complexes with lanthanides and actinides, among oth-

Conclusions
This review, covering the period of 1994-2024, discussed methods for the synthesis and applications of heteroarylphosphonates and their complexes with metals utilizing their optical properties.Heteroaryl moieties of the described compounds contain nitrogen and sulfur atoms in the ring, but the vast majority involve pyridine derivatives, and they are often associated with the easy availability of these derivatives and their good complex-forming properties.The introduction of phosphonate groups makes it possible to manipulate the electronic and optical properties of the described compounds, but also to anchor them on metal oxide surfaces for device applications.In the construction of optoelectronic devices based on D-π-A structure, the presence of phosphonate groups ensures
and 15, which could be rationalized by the raising π-conjugation.The NMR studies have shown that the OIHM exist as aluminum-phosphorus salts, i.e., [Al-OP(O)Ar-OH] or [Al-OP(O)ArO-Al].Further photochemical studies have shown that aluminum films made of 14 and 15 exhibit fluorescence resonance energy transfer (FRET) when the molar fraction of 14 exceeded 0.9.The complex of four equivalents of aluminum lactate and one equivalent of 15 were measured as having the highest fluorescence lifetime.

and 15 ,
which could be rationalized by the raising π-conjugation.The NMR studies have shown that the OIHM exist as aluminumphosphorus salts, i.e., [Al-OP(O)Ar-OH] or [Al-OP(O)ArO-Al].Further photochemical studies have shown that aluminum films made of 14 and 15 exhibit fluorescence resonance energy transfer (FRET) when the molar fraction of 14 exceeded 0.9.The complex of four equivalents of aluminum lactate and one equivalent of 15 were measured as having the highest fluorescence lifetime.Detty, Eisenberg, McCamant et al. synthesized a set of chalcogenorhodamine dyes 18-20 according to the previously reported procedures [19], in which the ring heteroatoms were O or Se (Figure

Scheme 3 .
Scheme 3. Synthesis of bis(aryl-and heteroaryl)phosphonic acids 13-17.Detty, Eisenberg, McCamant et al. synthesized a set of chalcogenorhodamine dyes 18-20 according to the previously reported procedures [19], in which the ring heteroatoms were O or Se (Figure 2) [20].The goal of the study was to deepen the understanding of the photophysical properties of chalcogenorhodamine dyes.The procedure is illustrated by the synthesis of compound 18 (Scheme 4).Molecules 2024, 29, x FOR PEER REVIEW 5 of 31

Scheme 7 .
Scheme 7. Synthetic protocol for the preparation of ligands 35 and 36.

Scheme 7 .
Scheme 7. Synthetic protocol for the preparation of ligands 35 and 36.

Scheme 7 .
Scheme 7. Synthetic protocol for the preparation of ligands 35 and 36.
Molecules 2024, 29, x FOR PEER REVIEW 16 of 31 classical carbonyl anchors.The synthesis consisted of the substitution of IrCl3 with different ligands, which were prepared according to the literature procedures or bought from commercial sources.

Figure 13 .
Figure 13.Chemical structures of ligands 91-94 and equilibrium A-D of 92 at different pH.

Polymers 22-26 showed
Emission of the free ligand was recorded at excitation wavelengths 250, 275, 300, 350 and 375 nm, and emission wavelengths were recorded at 306 and 331 nm.
no luminescence at ambient temperature, whereas polymer 26, when dissolved in acetonitrile, exhibited a weak emission at 313 nm.It was thought that room-temperature luminescence was too weak to be detected and required low-temperature measurements.